The answer to the first question is straightforward: it is `C(n,r)`

, where we are to choose all combinations of `r`

items from a set of size `n`

. The formula is here among other places:

```
C(n,r) = n! / (r! (n-r)!)
```

The ability to select the `i'th`

combination without computing all the others will depend on having an encoding that relates the combination number `i`

to the combination. That would be much more challenging and will require more thought ...

(EDIT)

Having given the problem more thought, a solution looks like this in Python:

```
from math import factorial
def combination(n,r):
return factorial(n) / (factorial(r) * factorial(n-r))
alphabet = "ABCDEFGHIJKLMNOPQRSTUVWXYZ"
def showComb(n,r,i,a):
if r < 1:
return ""
rr = r-1
nn = max(n-1,rr)
lasti = i
i -= combination(nn,rr)
j = 0
while i > 0:
j += 1
nn = max(nn-1,1)
rr = min(rr,nn) # corrected this line in second edit
lasti = i
i -= combination(nn,rr)
return a[j] + showComb(n-j-1,r-1,lasti,a[(j+1):])
for i in range(10):
print(showComb(5,3,i+1,alphabet))
```

... which outputs the list shown in the question.

The approach I've used is to find the first element of the `i'th`

output set using the idea that the number of combinations of the remaining set elements can be used to find which should be the first element for a given number `i`

.

That is, for C(5,3), the first C(4,2) (=6) output sets have 'A' as their first character, then the next C(3,1) (=3) output sets have 'B' then C(1,1) (=1) sets have 'C' as their first character.

The function then finds the remaining elements recursively. Note that `showComb()`

is tail-recursive so it could be expressed as a loop if you preferred, but I think the recursive version is easier to understand in this case.

For further testing, the following code may be useful:

```
import itertools
def showCombIter(n,r,i,a):
return ''.join(list(itertools.combinations(a[0:n],r))[i-1])
print ("\n")
# Testing for other cases
for i in range(120):
x = showComb(10,3,i+1,alphabet)
y = showCombIter(10,3,i+1,alphabet)
print(i+1,"\t",x==y,"\t",x,y)
```

... which confirms that all 120 examples of this case are correct.

I haven't calculated the time complexity exactly but the number of calls to `showComb()`

will be `r`

and the `while`

loop will execute `n`

times or fewer. Thus, in the terminology of the question, I am pretty sure the complexity will be less than O(M+N), if we assume that the `factorial()`

function can be calculated in constant time, which I don't think is a bad approximation unless its implementation is naive.